Percussion tool

ABSTRACT

A percussion tool comprises a housing and an electric motor positioned within the housing. The percussion tool further comprises a battery pack supported by the housing for providing power to the motor. The battery pack includes a plurality of battery cells having a nominal voltage of up to 120 Volts. The percussion tool further comprises a percussion mechanism driven by the motor and including a striker supported for reciprocation in the housing. The percussion tool has a ratio of impact energy to mass that is greater than or equal to 2.5 Joules/kilogram.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a continuation of co-pending U.S. patent application Ser. No. 16/668,608 filed on Oct. 30, 2019, which is a continuation of U.S. patent application Ser. No. 16/257,600 filed on Jan. 25, 2019, which claims priority to U.S. Provisional Patent Application No. 62/650,737 filed on Mar. 30, 2018, and U.S. Provisional Patent Application No. 62/622,615 filed on Jan. 26, 2018, the entire contents of all of which are incorporated herein by reference.

FIELD OF THE INVENTION

The present invention relates to power tools, and more particularly to percussion tools.

BACKGROUND OF THE INVENTION

Percussion tools, such as breakers, impart axial impacts to an attached chisel to demolish a work surface. Such tools can include an anti-vibration system to attenuate vibration transmitted to the operator. Such tools also include tool holders to alternatively hold or release chisel bits for performing a breaking operation.

SUMMARY OF THE INVENTION

The present invention provides, in yet another aspect, a percussion tool comprising a housing and an electric motor positioned within the housing. The percussion tool further comprises a battery pack supported by the housing for providing power to the motor. The battery pack includes a plurality of battery cells having a nominal voltage of up to 120 Volts. The percussion tool further comprises a percussion mechanism driven by the motor and including a striker supported for reciprocation in the housing. The percussion tool has a ratio of impact energy to mass that is greater than or equal to 2.5 Joules/kilogram.

The present invention provides, in yet another aspect, a percussion tool comprising a housing and an electric motor positioned within the housing. The percussion tool further comprises a battery pack supported by the housing for providing power to the motor. The battery pack includes a plurality of battery cells having a nominal voltage of up to 120 Volts. The percussion tool further comprises a percussion mechanism driven by the motor and including a striker supported for reciprocation in the housing. The percussion tool has a ratio of blow power to mass that is greater than or equal to 50 W/kg.

The present invention provides, in yet another aspect, a percussion tool comprising a housing and an electric motor positioned within the housing. The percussion tool further comprises a battery pack supported by the housing for providing power to the motor. The battery pack includes a plurality of battery cells having a nominal voltage of up to 120 Volts. The percussion tool further comprises a percussion mechanism driven by the motor and including a striker supported for reciprocation in the housing. The percussion tool delivers greater than or equal to 85 kJ of impact energy per minute.

Other features and aspects of the invention will become apparent by consideration of the following detailed description and accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a percussion tool in accordance with an embodiment of the invention.

FIG. 2 is a cross-sectional view of the percussion tool of FIG. 1.

FIG. 3 is a plan view of the percussion tool of FIG. 1 with portions removed.

FIG. 4 is a cross-sectional view of the percussion tool of FIG. 1 along section 4-4 in FIG. 1.

FIG. 5 is a perspective view of the percussion tool of FIG. 1 with portions removed.

FIG. 6 is a perspective view the percussion tool of FIG. 1 with portions removed.

FIG. 7 is a side view of the percussion tool of FIG. 1.

FIG. 8 is a top view of the percussion tool of FIG. 1.

FIG. 9 is a front view of another embodiment of the percussion tool of FIG. 1.

FIG. 10 is a front plan view of yet another embodiment of the percussion tool of FIG. 1.

FIG. 11 is a top plan view of the percussion tool of FIG. 10.

FIG. 12 is a plan view of the percussion tool of FIG. 1 with a battery removed.

FIG. 13 is a block diagram of the percussion tool of FIG. 1.

FIG. 14 is a flowchart of a method for reducing vibrations in the percussion tool of FIG. 1.

FIG. 15 is a graph illustrating the variation in motor speed in no-load and loaded conditions of the percussion tool of FIG. 1.

FIG. 16 is a graph illustrating the variation in motor current in no-load and loaded conditions of the percussion tool of FIG. 1.

FIG. 17 is a flowchart of a method for determining whether the tool of FIG. 1 is in a no-load condition.

FIG. 18 is a flowchart of another method for determining whether the tool of FIG. 1 is in a no-load condition.

FIG. 19 is a flowchart of another method for determining whether the tool of FIG. 1 is in a no-load condition.

FIG. 20 is a perspective view of a percussion tool according to another embodiment of the invention.

FIG. 21 is a perspective view of the percussion tool of FIG. 20.

FIG. 21 is a cross-sectional view of the percussion tool of FIG. 20.

FIG. 23 is a perspective view of the percussion tool of FIG. 20.

FIG. 24 is a cross-sectional view of the percussion tool of FIG. 20.

FIG. 25 is a schematic view of the percussion tool of FIG. 20.

FIG. 26 is a perspective view of a battery pack of the percussion tool of FIG. 20.

FIG. 27 is a cross-sectional view of the battery pack of FIG. 26.

FIG. 28 is a cross-sectional view of a motor of the percussion tool of FIG. 20.

Before any embodiments of the invention are explained in detail, it is to be understood that the invention is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The invention is capable of other embodiments and of being practiced or of being carried out in various ways. Also, it is to be understood that the phraseology and terminology used herein is for the purpose of description and should not be regarded as limiting.

DETAILED DESCRIPTION

FIG. 1 illustrates a percussion tool, such as a breaker 10, according to an embodiment of the invention. The breaker 10 includes a housing 14, a brushless electric motor 18 supported within a crank case 20 (FIG. 2), and a percussion mechanism 22 driven by the motor to impart repeated percussive impacts on a surface or workpiece via a chisel 24 (FIGS. 9, 10 and 12). The housing 14 includes a top end 15, a bottom end 16, a front side 17, and a rear side 19 behind which the operator stands to operate the breaker 10. The breaker 10 includes a battery pack 26 (FIG. 1) that is attachable to the front side 17 of the housing 14 and configured to provide electrical power to the motor 18. The battery pack 26 may include any of a number of different nominal voltages (e.g., 12V, 18V, etc.), and may be configured having any of a number of different chemistries (e.g., lithium-ion, nickel-cadmium, etc.). In the illustrated embodiment, the battery pack 26 includes a battery pack housing 468 and a plurality of individual battery cells 480 within the battery pack housing 468 (FIG. 27), as described in further detail below. The battery pack 26 is removable from the housing 14 for attachment to a remote charging station. As discussed in further detail below, the breaker 10 further includes a controller 250 (FIG. 25) for activating and deactivating the motor 18 in response to user input.

The chisel 24 is mounted within a tool holder 30 of the breaker 10. The tool holder 30 includes a rotatable handle 34 including a locking rod 38 within a recess 42 of the tool holder 30. When the handle 34 is rotated to the position shown in FIGS. 1, 4, 7, 9, 10, 12 and 20 the locking rod 38 moves to a position to engage a longitudinal groove of the chisel 24 to prevent the chisel 24 from falling out when the tool holder 30 is oriented downwardly. A similar locking rod and chisel is described and illustrated in U.S. patent application Ser. No. 16/164,000 filed on Oct. 18, 2018, the entire content of which is incorporated herein by reference.

As shown in FIG. 2, the breaker 10 also includes a gear train 46 rotationally supported by the crank case 20 for transmitting torque from the motor 18 to the percussion mechanism 22. The percussion mechanism 22 includes a crank shaft 50 having an eccentric pin 54, a reciprocating piston 58 disposed within a cylinder 62 extending from the bottom side 16 of the housing 14, and a connecting rod 66 interconnecting the piston 58 and the eccentric pin 54. The percussion mechanism 22 also includes a striker 70 (FIG. 4) that is selectively reciprocable within the cylinder 62 in response to reciprocation of the piston 58. The striker 70 defines a first, striker axis 74 along which the striker 70 is configured to impart repeated axial impacts to the chisel 24 in the tool holder 30 in response to reciprocation of the piston 58. An anvil (not shown) may optionally be positioned between the striker 70 and chisel 24 to transmit the axial impacts from the striker 70 to the chisel 24.

With reference to FIG. 3, the breaker 10 includes an anti-vibration system 78 for attenuating vibration in the direction of the striker axis 74. The anti-vibration system 78 includes a linkage 82 coupling the percussion mechanism 22 to the housing 14 to permit relative movement between the housing 14 and the percussion mechanism 22 along the striker axis 74. In the illustrated embodiment, the linkage 82 includes a first swing arm 86, a second swing arm 90, and a third swing arm 94 that pivotally couple and support the crank case 20 with respect to the housing 14. Specifically, the first and second swing arms 86, 90 are respectively coupled to the housing 14 via pivots 98, 102 on opposite internal sides of the housing 14, and are respectively coupled to the crank case 20 via pivots 106, 110. The first and second swing arms 86, 90 are also coupled to each other via a cross bar 112 extending over the crank case 20 on a side opposite the cylinder 62, thus causing the first and second swing arms 86, 90 to swing together. The pivots 98, 102 define a first swing axis 114 about which the swing arms 86, 90 may swing. Unlike the first and second swing arms 86, 90, the third swing arm 94 extends around the crank case 20. The third swing arm 94 is coupled to the housing 14 via pivots 118, 122 on opposite internal sides of the housing 14 and is coupled to the crank case 20 via pivots 126, 130. The pivots 118, 122 define a second swing axis 134 about which the third swing arm 94 may swing. The second swing axis 134 is parallel to the first swing axis 114.

As shown in FIGS. 3 and 5, the anti-vibration system 78 further includes a leaf spring 138 on the side of the crank case 20 opposite the cylinder 62 and a foam bumper 142 arranged between the housing 14 and the crank case 20 on the side opposite the battery pack 26. The leaf spring 138 is coupled to an interior of the top end 15 of the housing 14 and the foam bumper 142 is coupled to an interior of the rear end of the housing 14. In some embodiments, one portion of the leaf spring 138 is anchored to the housing 14 and another portion is coupled to the crank case 20. As shown in FIG. 6, the anti-vibration system 78 also includes a shake weight, such as a counterweight 146. Four compression springs 150 bias the counterweight 146 along a counterweight axis 154 that is parallel with the striker axis 74. Specifically, in the illustrated embodiment, two of the compression springs 150 are arranged on one side of the counterweight 146 to bias it in a first direction along the counterweight axis 154 and two compression springs 150 are arranged on an opposite side of the counterweight 146 to bias it in an opposite, second direction. The springs 150 are identical, thus biasing the counterweight 146 toward the neutral position shown in FIG. 6. However, in other embodiments there could be just one spring 150 on each side of the counterweight 146, or more than two springs 150.

In the illustrated embodiment, the counterweight 146 is arranged completely within the crank case 20, but in other embodiments, the counterweight 146 could be completely outside the crank case 20 but within housing 14, or partially within the crank case 20. In some embodiments, the mass of the counterweight 146 is between 500 grams and 1,000 grams. The natural frequency of the anti-vibration system 78 is between 20 Hz and 23 Hz, which is the expected operating frequency of the percussion mechanism 22.

As shown in FIGS. 1 and 7, the housing 14 includes opposite=first and second sides 156, 157 that extend between the front and rear sides 17, 19. The breaker 10 includes opposite first and second operating handles 158, 160 respectively extending from the first and second lateral sides 156, 157 and together defining a second, handle axis 162. The striker axis 74 is contained within a first, striker plane 166 and the handle axis 162 is contained within a second, handle plane 170 that is parallel with the striker plane 166. The striker plane 166 and the battery pack 26 are on opposite sides of the handle plane 170. The handle plane 170 intersects a center of gravity (CG) of the breaker 10, which is forward of the striker plane 166 yet rearward of the battery pack 26 because the battery pack 26 is coupled to the front side 17 of the housing 14. Thus, when an operator picks up the breaker 10 via the first and second handles 158, 160, the cylinder 62 and chisel 24 point straight downward, such that the striker axis 74 can be maintained perpendicular to the ground without the breaker 10 exerting a moment about its center of gravity (CG) that must otherwise be counteracted by the operator.

In other embodiments (not shown), the battery pack 26 may be coupled to the rear side 19 of the housing 14, and the first and second handles 158, 160 are accordingly arranged rearward of the striker plane 166, such that handle plane 170 intersects the (CG) which is also rearward of the striker plane 166. In other embodiments (not shown), the battery pack 26 may be coupled to the top end 15 of the housing 14 (opposite the cylinder 62) and depending on whether the battery pack 26 adds more weight forward of or rearward of the striker plane 166, the first and second handles 158, 160 and the handle plane 170 may be offset of the striker plane 166 accordingly.

As shown in FIGS. 1 and 8-12, the breaker 10 also includes a guard 174 coupled to the housing 14 and at least partially surrounding the battery pack 26, thereby shielding the surrounded portion of the battery pack 26 from an external impact. As shown in FIG. 8, when the battery pack 26 is coupled to the front side 17 of the housing 14, the battery pack 26 extends a first distance 178 from a surface 182 on the front side 17 of the housing 14. As also shown in FIG. 8, the guard 174 includes a first guard member 186 and a second guard member 190 that both extend a second distance 194 from the surface 182. The first and second guard members 186, 190 are arranged on opposite sides of the battery pack 26 when the battery pack 26 is coupled to the front side 17 of the housing 14.

As shown in FIGS. 1, 8, and 9, a cross member 198 extends between the first and second guard members 186, 190. In the embodiments shown in FIGS. 1 and 8, the cross member 198 is a solid plate 202. However, in another embodiment shown in FIG. 9, the cross member 198 can be one or more bars 206. In still other embodiments shown in FIGS. 10 and 11, there is no cross member between the first and second guard members 186, 190. As shown in FIG. 12, in which the battery pack 26 is removed from the housing 14, and in any of the embodiments described in FIGS. 8-11, the first and second guard members 186, 190 are configured as open rails that define a space 210 within them. In other embodiments, the first and second guard members 186, 190 may be solid without an internal space defined therein.

In operation, an operator first grasps the first and second handles 158, 160 to pick up the breaker 10. As described above, because the handle plane 170 intersects the center of gravity (CG) of the breaker 10, the cylinder 62 and chisel 24 point straight downward, such that the striker axis 74 can be maintained perpendicular to the ground without the breaker 10 exerting a moment about its center of gravity (CG) that must otherwise be counteracted by the operator. This requires the operator to exert less effort when using the breaker 10.

When the motor 18 is activated, the gear train 46 transmits torque from the motor 18 to the crank shaft 50 of the percussion mechanism 22. As the crank shaft 50 rotates, so does the eccentric pin 54. Rotation of the eccentric pin 54 causes the piston 58 to reciprocate within the cylinder 62 via the connecting rod 66, which causes the striker 70 to impart axial blows to the chisel 24, which in turn causes reciprocation of the chisel 24 against a workpiece. Specifically, a variable pressure air pocket (or an air spring) is developed between the piston 58 and the striker 70 when the piston 58 reciprocates within the cylinder 62, whereby expansion and contraction of the air pocket induces reciprocation of the striker 70. The impact of the striker 70 on the chisel 24 causes it to reciprocate for performing work on a surface or workpiece.

In response to the piston 58 and striker 70 reciprocating within the cylinder 62 along the striker axis 74, the counterweight 146 oscillates along the counterweight axis 154, but out of phase with the percussion mechanism 22, to attenuate vibration in the direction of the striker axis 74. In some embodiments, the counterweight 146 reduces the loaded vibration of the breaker 10 by about 10% as compared to vibration of the breaker 10 in embodiments without the counterweight 146.

In response to the piston 58 and striker 70 reciprocating within the cylinder 62, the crank case 20 also experiences vibration along the striker axis 74 as a result of the reaction forces applied to the chisel 24 during operation. As the crank case 20 experiences vibration, the first and second swing arms 86, 90 swing about the first swing axis 114 and the third swing arm swings about the second swing axis 134 to permit the crank case 20 to oscillate along the striker axis 74 with respect to the housing 14, thereby attenuating the vibration transmitted from the crank case 20 to the operator via the housing 14. As the crank case 20 oscillates, the crank case 20 may abut against the leaf spring 138 and the foam bumper 142, which also attenuates the vibration transmitted to the operator through the crank case 20 and housing 14.

If the operator accidently drops the breaker tool 10 during operation or during an idle, non-operative state, the breaker 10 may fall forward in a direction led by the battery pack 26, which is coupled to the front side 17 of the housing 14. However, instead of the battery pack 26 striking a surface, one or more of the first guard member 186, the second guard member 190, or the cross member 198 of the guard 174 would strike the surface, thereby absorbing the impact of the fall and preventing damage to the battery pack 26.

FIG. 13 is a simplified block diagram of the breaker 10. In the example illustrated, the breaker 10 includes the battery pack 26, a controller 250 (also referred to as an electronic controller), an inverter bridge 254, the motor 18, a rotational speed sensor 258, one or more current sensors 262, and a trigger 266. The controller 250 includes a memory storing instructions executed by an electronic processor to carry out the functions of the controller 250 described herein. For example, in some embodiments, the controller 250 may be implemented as a microprocessor with a separate memory. In other embodiments, the controller 250 may be implemented as a microcontroller (with memory on the same chip). In other embodiments, the controller 250 may be implemented using multiple processors. In addition, the controller 250 may be implemented partially or entirely as, for example, a field programmable gate array (FPGA), an application specific integrated circuit (ASIC), etc., and the memory may not be needed or be modified accordingly.

The inverter bridge 254 includes a plurality of field effect transistors (FETs) that are used to control the power supply to the motor 18. The controller 250 provides pulse width modulated (PWM) signals to control the FETs of the inverter bridge 254 based on user input. Thereby, the controller 250 may increase or decrease the speed of the motor 18 by increasing or decreasing the duty cycle of the PWM signals.

The rotational speed sensor 258 is provided near or attached to the motor 18 to detect the rotational speed of the motor 18. In some embodiments, the rotational speed sensor 258 may be a Hall-effect sensor that detects an angular position or angular speed of the permanent magnets of the motor 18. The one or more current sensors 262 may be, for example, current sense resistors that provide an indication of an amount of current flowing to the motor 18 to the controller 250. In one example, the breaker 10 includes three current sensors 262, one per each phase of the motor 18. The three current sensors 262 are provided on phase lines connecting the inverter bridge 254 to the motor 18. In some embodiments, the controller 250 communicates with a battery pack controller (not shown) to receive information regarding the battery pack. For example, the controller 250 may receive instantaneous or average values of the battery pack voltage from the battery pack controller.

Although the anti-vibration system 78 is effective in reducing vibrations during a loaded condition, an additional mechanism may be used to reduce vibrations during a no-load condition. The breaker 10 is in a no-load condition when the chisel 24 is not in contact with and/or acting on a work surface or a workpiece. The breaker 10 is in a loaded condition when the chisel 24 is in contact with and acting on a work surface or a workpiece. Generally, the motor 18 operates at a higher speed during a no-load condition in contrast to a loaded condition.

FIG. 14 is a flowchart illustrating one example method 270 of reducing vibrations in the breaker 10. As illustrated in FIG. 14, the method 270 includes activating, using the controller 250, the motor 18 (at block 274). The motor 18 may be activated in response to a user turning on a power switch or pulling the trigger 266 of the breaker 10. The method 270 also includes determining, using the controller 250, whether the breaker 10 is in a loaded condition (at block 278). Several techniques may be used to detect whether the breaker 10 is in a loaded condition. Exemplary techniques of determining whether the breaker 10 is in a loaded condition based on detecting the motor speed (FIGS. 17 and 19) and detecting current or voltage measurements (FIGS. 18 and 19) are explained below.

In response to the controller 250 determining that the breaker 10 is in a loaded condition, the method 270 includes operating, using the controller 250, the motor 18 in accordance with a predetermined profile (for example, a predetermined speed profile) (at block 282). The predetermined profile may be, for example, a normal loaded condition control of the motor 18. In some embodiments, the controller 250 may provide a constant power output to the motor 18 when the breaker 10 is in the loaded condition and the trigger 266 is depressed. In other embodiments, the controller 250 may vary the speed of the motor 18 in proportion to the actuation amount of the trigger 266 (i.e., when the trigger 266 is a variable speed trigger) when the breaker is in the loaded condition.

When the controller 250 determines that the breaker 10 is in a no-load condition, the method 270 includes operating, using the controller 250, the motor 18 with reduced speed (for example, at a no-load speed) (at block 286). For example, the controller 250 may operate the motor 18 at 50% of maximum speed by driving the inverter bridge 254 with a 50% PWM duty cycle. In some embodiments, the controller 250 may operate the motor 18 at a constant no-load speed that is lower than the speed in the loaded condition when no-load is detected. In other embodiments, in the no-load state, the controller 250 may operate the motor 18 at a speed that is, for example, 50% of the speed that corresponds to the actuation amount of a variable speed trigger. Reducing the speed in the no-load condition further reduces the vibrations experienced by a user of the breaker 10.

In some embodiments, the method 270 continuously loops while the motor 18 is activated (e.g., while the trigger 266 remains depressed). In other words, after proceeding to step 286 and operating the motor with reduced speed and after proceeding to step 282 and operating the motor in accordance with a predetermined profile, the controller 250 returns to step 278 to re-evaluate whether the breaker is in a loaded condition using updated sensor data.

FIG. 15 illustrates a graph of motor speed versus time showing the variation in motor speed during no-load and loaded conditions. As shown in FIG. 15, the motor 18 operates in a loaded condition at 290. In the loaded condition, the motor 18 is operated at a maximum power or a power corresponding to a trigger pull. When the breaker 10 is unloaded, for example, at 294, the motor speed increases as the breaker 10 is no longer acting on a workpiece. Additionally, when the breaker 10 is unloaded, for example, at 294, the variation in motor speed decreases. Based on the motor speed and/or variation in motor speed, the controller 250 determines that breaker 10 is in a no-load condition at 294 (e.g., at block 286 of FIG. 14) and reduces the power output to the motor 18 such that the motor can operate at a no-load speed at 298. When the breaker 10 subsequently acts upon a load when under no-load control, for example, at 302, the motor speed decreases due to the tip tool contacting and acting on the workpiece. Additionally, when the breaker 10 acts upon the load, for example, at 302, the variation in motor speed increases. Based on the motor speed and/or variation in motor speed, the controller 250 determines that the breaker 10 is in the loaded condition (e.g., in block 282 of FIG. 14) and switches operation to the loaded mode operation at 306 as described above.

FIG. 16 illustrates a graph of motor current versus time showing the variation in motor current during no-load and loaded conditions. As shown in FIG. 16, the motor 18 operates in a loaded condition at 310. In the loaded condition, the motor 18 is operated at a maximum power or a power corresponding to a trigger pull. When the breaker 10 is unloaded, for example, at 314, the motor current decreases as the breaker 10 is no longer acting on a workpiece. Additionally, when the breaker 10 is unloaded, for example, at 314, the variation in motor current also decreases. Based on the motor current and/or variation in motor current, the controller 250 determines that breaker 10 is in a no-load condition at 314 (e.g., at block 286 of FIG. 14) and reduces the power output to the motor 18 such that the motor can operate at a no-load speed at 318. When the breaker 10 subsequently acts upon a load when under no-load control, for example, at 322, the motor current increases due to the tip tool contacting and acting on the workpiece. Additionally, when the breaker 10 acts upon the load, for example, at 322, the variation in motor current also increases. Based on the motor current and/or variation in motor current, the controller 250 determines that the breaker 10 is in the loaded condition (e.g., in block 282 of FIG. 14) and switches operation to the loaded mode operation at 326 as described above.

The variation in motor current or speed is determined by calculating, for example, a variance, a standard deviation, a mean, or an average of motor current or speed values over a time period.

FIG. 17 is a flowchart illustrating one example method 330 for determining whether the breaker 10 is in a no-load condition. As illustrated in FIG. 17, method 330 includes detecting, using the controller 250 with the rotational speed sensor 258, a motor speed (at block 334). In some embodiments, the rotational speed sensor 258 may provide signals indicating the angular speed (i.e., motor speed) of the motor shaft to the controller 250. In other embodiments, the rotational speed sensor 258 may provide an angular position of the motor shaft to the controller 250. In these embodiments, the controller 250 may calculate the motor speed based on the angular positions of the motor shaft. For example, the rotational speed sensor 258 may be a Hall sensor that outputs a pulse to the controller 250 each time a rotor magnet passes across the face of the sensor. For example, the rotational speed sensor 258 may include three Hall sensors each of which outputs a pulse to the controller 250 when the rotor magnet passes across the face of that Hall sensor. The controller 250, in turn, can calculate the speed of the motor by the number of pulses received per time period (e.g., per second). The controller 250 stores the measured speed in a memory. The stored measurements are later used to calculate the average, variance, and other quantities.

The method 330 further includes determining, using the controller 250, whether the motor speed satisfies a first speed threshold (for example, a loaded condition speed threshold) (at block 338). The controller 250 compares the motor speed to the first speed threshold to determine whether the motor speed satisfies the first speed threshold. In some embodiments, the controller 250 may compare an instantaneous motor speed to the first speed threshold. In other embodiments, the controller 250 may compare an average motor speed over a time period to the first speed threshold. For example, the controller 250 may calculate the average motor speed over the past 10 milliseconds or over the past 1 second and compare the average motor speed to the first speed threshold.

In response to the controller 250 determining that the motor speed satisfies the first speed threshold, the controller 250 determines that the breaker 10 is in a no load condition (at block 342). In turn, returning to FIG. 14, the controller 250 then proceeds to reduce the motor speed (see block 286). In response to the controller 250 determining that the motor speed does not satisfy the first speed threshold, the controller 250 determines that the breaker 10 is in a loaded condition (at block 346). In turn, returning to FIG. 14, the controller 250 operates the motor 18 in accordance with a predetermined profile (see block 310).

Once the controller 250 determines that the breaker 10 is in the no-load condition, the controller 250 switches to using a second speed threshold to determine whether a load is subsequently applied to the breaker 10 as described below. The second speed threshold is lower than the first predetermined speed threshold. As described above in FIG. 14, the breaker 10 operates at a reduced speed in the no-load state. As such, the first speed threshold will not be accurate in determining whether a load is subsequently applied. The method 330 includes detecting, using the controller 250 with the rotational speed sensor 258, the motor speed (at block 350). The controller 250 periodically detects the motor speed. For example, the controller 250 may determine the motor speed every few microseconds.

The method 330 also includes determining, using the controller 250, whether the motor speed satisfies the second speed threshold (for example, a no-load condition speed threshold) (at block 354). The controller 250 compares the motor speed to the second speed threshold. In response to the controller 250 determining that the motor speed does not satisfy the second speed threshold, the controller 250 determines that the breaker 10 is in the loaded condition (at block 346). Once the controller 250 determines that the breaker 10 is in the loaded condition, the controller 250 returns to step 334 and switches back to comparing the motor speed to the first speed threshold to determine whether the breaker 10 is subsequently unloaded. In response to the controller 250 determining that the motor speed satisfies the second predetermined speed threshold, the method 330 returns to block 342 to determine that the breaker 10 is in the no load condition as described above.

In the above example, the motor speed satisfies the first speed threshold or the second speed threshold when the motor speed exceeds the first speed threshold or the second speed threshold respectively. The motor speed does not satisfy the first speed threshold or the second speed threshold when the motor speed is below the first speed threshold or the second speed threshold respectively. In other examples, the motor speed satisfies the first speed threshold or the second speed threshold when the motor speed falls below the first speed threshold or the second speed threshold respectively. The motor speed does not satisfy the first speed threshold or the second speed threshold when the motor speed is above the first speed threshold or the second speed threshold respectively.

FIG. 18 is a flowchart illustrating another example method 358 of determining whether the breaker 10 is in a no-load condition. As illustrated in FIG. 18, the method 358 includes detecting, using the controller 250 with the one or more current sensors 262, a motor current (at block 362). As described above, the one or more current sensors 262 may be a current sense resistor that provides an indication of an amount of current flowing to the motor 18 to the controller 250. In some embodiments, the amount of expected motor current in a load and no-load condition may vary based on the voltage of the battery pack 26. In these embodiments, the controller 250 may use the battery pack voltage measurement to weight the measured current values. For example, when the battery pack 26 has a first, higher voltage (e.g., when fully charged), the expected motor current in a loaded and no-load condition may be higher than when the battery pack 26 has a second, lower voltage (e.g., after the battery pack is partially drained through usage of the breaker 10). Accordingly, the controller 250 may determine the battery pack voltage in block 350, and weight the detected current by multiplying the detected current by a value inversely proportional to the voltage of the battery pack 26. In some embodiments, the controller 250 may also weight the measured current values based on a historical values of motor current (for example, based on how the current has been performing in the past for a certain condition). Thus, in some embodiments, the detected motor current in step 350 is an adjusted current weighted based on the voltage of the battery pack 26 or past current performance. Detected motor speed and detected motor speed variation may be similarly weighted based on the voltage of the battery pack 26 or the past speed performance. Alternatively, in another embodiment, the voltage of the battery pack 26 or the past motor performance is used to adjust the motor speed thresholds (that is, the first speed threshold and the second speed threshold), the motor speed/current variation threshold (described below with respect to FIG. 19), and/or a motor current thresholds (that is, a first current threshold and a second current threshold as described below). For example, the motor speed thresholds, the motor speed/current variation threshold, and/or the motor current thresholds are multiplied by a value inversely proportional to the voltage of the battery pack 26. The controller 250 stores the measured current values in a memory. The stored measurements are later used to calculate the average, variance, and other quantities.

The method 358 further includes determining, using the controller 250, whether the motor current satisfies a first current threshold (for example, a loaded condition current threshold) (at block 366). The controller 250 compares the motor current or the updated motor current to the first current threshold to determine whether the motor current satisfies the first current threshold. In some embodiments, the controller 250 may compare an instantaneous motor current to the first current threshold. In other embodiment, the controller 250 may compare an average motor current over a time period to the first current threshold. For example, the controller 250 may calculate the average motor current over the past 10 milliseconds or over the past 1 second and compare the average motor current to the first current threshold.

In response to the controller 250 determining that the motor current does not satisfy the first current threshold, the controller 250 determines that the breaker 10 is in a no-load condition (at block 370). In response to the controller 250 determining that the motor current satisfies the first current threshold, the controller 250 determines that the breaker 10 is in a loaded condition (at block 374).

Once the controller 250 determines that the breaker 10 is in the no-load condition, the controller 250 switches to using a second current threshold to determine whether a load is subsequently applied to the breaker 10 as described below. The second current threshold is lower than the first current threshold. The method 358 includes detecting, using the controller 250 with the one or more current sensors 262, the motor current (at block 380). The controller 250 periodically detects the motor current. For example, the controller 250 may determine the motor current every few microseconds.

The method 358 also includes determining, using the controller 250, whether the motor current satisfies the second current threshold (for example, a no-load condition current threshold) (at block 384). The controller 250 compares the motor current to the second current threshold. In response to the controller 250 determining that the motor current satisfies the second current threshold, the controller 250 determines that the breaker 10 is in a loaded condition (at block 374). Once the controller 250 determines that the breaker 10 is in the loaded condition, the method 290 switches back to comparing the detected current to the first current threshold to determine whether the breaker 10 is subsequently unloaded. In response to the controller 250 determining that the motor current does not satisfy the second current threshold, the controller 250 determines that the breaker 10 is in a no load condition (at block 370) as described above. In some embodiments, the motor current, the first current threshold and/or the second current threshold is adjusted based on the voltage of the battery pack 26 or historical current performance as described above.

In the above example, the motor current satisfies the first current threshold or the second current threshold when the motor current exceeds the first current threshold or the second current threshold respectively. The motor current does not satisfy the first current threshold or the second current threshold when the motor current is below the first current threshold or the second current threshold respectively. In other examples, the motor current satisfies the first current threshold or the second current threshold when the motor current falls below the first current threshold or the second current threshold respectively. The motor current does not satisfy the first current threshold or the second current threshold when the motor current is above the first current threshold or the second current threshold respectively.

In some embodiments, hysteresis may be used to prevent frequent switching between the different operations of the breaker 10. For example, instead of two thresholds of different values, a single initial threshold may be used, but updated to provide hysteresis when the controller 250 determines that the tool has changed from a loaded condition to a no-load condition, and vice-versa. More particularly, when the tool is in a no-load condition and the controller 250 determines that the current has satisfied the threshold in step 384, the controller 250 proceeds to block 374 to determine that the breaker 10 is now in a loaded condition. Upon entering block 374, the controller 250 also reduces the threshold (e.g., to a value between 60-90% of the initial predetermined threshold). This reduced threshold may be used by the controller when subsequently executing step 366. In some embodiments, this reduced threshold is used for a certain amount of time or number passes through block 366, and then the controller 250 returns the threshold to its initial value. Similarly, when the tool is in a loaded condition and the controller 250 determines that the current no longer satisfies the threshold in step 366, the controller 250 proceeds to block 370 to determine that the breaker 10 is now in a no-load condition. Upon entering block 370, the controller 250 also increases the threshold (e.g., to a value between 110-140% of the initial threshold). This increased threshold may be used by the controller when subsequently executing step 384. In some embodiments, this increased threshold is used for a certain amount of time or number passes through block 384, and then the controller 250 returns the threshold to its initial value. In some embodiments, to provide hysteresis, the controller 250 may turn off determining whether the current has satisfied a threshold for a certain amount of time. For example, the controller 250 may implement a timer after switching from the loaded condition to the no-load condition or from the no-load condition to the loaded condition before the controller 250 next determines whether the current satisfies the threshold value.

FIG. 19 is a flowchart illustrating another example method 388 of determining whether the breaker 10 is in a no-load condition. As illustrated in FIG. 19, the method 388 includes detecting, using the controller 250 with a sensor, a motor characteristic (at block 392). The motor characteristic is, for example, the motor speed, the motor current, a voltage provided to the motor, or the like. The controller 250 uses one or more sensors to detect the motor characteristic. For example, the controller 250 uses rotational speed sensor 258 to determine the motor speed and uses the one or more current sensors 262 to determine the motor current.

The method 388 further includes determining, using the controller 250, a variation in the motor characteristic (at block 396) over a time period. The time period may be, for example, 10 milliseconds or 1 second. In some embodiments, determining the variation includes calculating, for example, a variance, a standard deviation, a mean, an average, or the like of the motor characteristic values over the time period. The variance in the motor characteristic is calculated by averaging the squared difference of each sample of motor characteristic value from a mean motor characteristic value within the time period. For example, the controller 250 determines a variation in motor speed, motor current, or the like. As described above, the controller 250 stores speed and current measurements in a memory to calculate the variation over a given period of time.

The method 388 also includes determining, using the controller 250, whether the variation in motor characteristic satisfies a characteristic variation threshold (at block 354). The controller 250 compares the variation in motor characteristic to the characteristic varition threshold. In one example, the controller 250 compares the variance in motor speed to a speed variance threshold. In another example, the controller 250 compares the variance in motor current to a current variance threshold. In response to the controller 250 determining that the variance in motor characteristic does not satisfy the predetermined characteristic variance threshold, the controller 250 determines that the breaker 10 is in the no-load condition (at block 404). In turn, returning to FIG. 14, the controller 250 then proceeds to reduce the motor speed (see block 286).

In response to the controller 250 determining that the motor characteristic satisfies the characteristic variation threshold, the controller 250 determines that the breaker 10 is in the loaded condition (at block 408). In turn, returning to FIG. 14, the controller 250 operates the motor 18 in accordance with a predetermined profile (see block 310).

In the above example, the motor characteristic satisfies the characteristic variation threshold when the motor characteristic exceeds the characteristic variation threshold and the motor characteristic does not satisfy the characteristic variation threshold when the motor characteristic is below the characteristic variation threshold. In other examples, the motor characteristic satisfies the characteristic variation threshold when the motor characteristic falls below the characteristic variation threshold and the motor characteristic does not satisfy the characteristic variation threshold when the motor characteristic is above the characteristic variation threshold respectively.

In some embodiments, rather than the motor characteristic variation, the controller 250 may use other motor characteristic profiles to determine whether the breaker is in a loaded condition or a no-load condition. Other characteristic profiles may include, for example, a motor characteristic curve (e.g., motor speed curve, motor current curve) or the like. In these embodiments, the controller 250 measures the motor characteristic values over a time period and determines a measured characteristic profile based on the measured motor characteristic values. The controller 250 compares the measured characteristic profile to a known characteristic profile that is stored in a memory of the controller 250. Similar to the above described examples, the controller 250 determines whether the breaker is in a loaded condition or a no-load condition based on comparing the measured characteristic profile to the known characteristic profile. For example, when the measured characteristic profile varies from the known characteristic profile by more than a particular amount (i.e., the measured characteristic satisfies the known characteristic profile), the controller 250 determines that the breaker is loaded (or in a no-load condition, depending on the embodiment). As another example, when the measured characteristic profile varies from the known characteristic profile by less than a particular amount (i.e., the measured characteristic profile does not satisfy the known characteristic profile), the controller 250 determines that the breaker is loaded (or in a no-load condition, depending on the embodiment).

After proceeding to step 404 and operating the motor with reduced speed and after proceeding to step 408 and operating the motor in accordance with a predetermined profile, the controller 250 returns to step 392 to re-evaluate whether the breaker is in a loaded condition using updated sensor data. That is, the controller 250 continuously detects the motor characteristic and updates the variation in motor characteristic or the measured characteristic profile to determine the load state of the breaker 10.

As illustrated in FIGS. 15 and 16, the motor speed and motor current vary to a larger degree when the breaker 10 is loaded than when the breaker 10 is unloaded. The method 388 detects the variation in the motor characteristic to determine a load condition of the breaker 10. In some embodiments, hysteresis may be used to prevent frequent switching between the different operations of the breaker 10. For example, the threshold may be updated to provide hysteresis after step 400 when the controller 250 determines that the tool has changed from a loaded condition to a no-load condition, and vice-versa. More particularly, when the tool is in a no-load condition and the controller 250 determines that the variation has satisfied the threshold in step 400, the controller 250 proceeds to block 408 to determine that the breaker 10 is now in a loaded condition. Upon entering block 408, the controller 250 also reduces the threshold (e.g., to a value between 60-90% of the initial threshold). This reduced threshold may be used by the controller when subsequently executing step 396. In some embodiments, this reduced threshold is used for a certain amount of time or number passes through block 396, and then the controller 250 returns the threshold to its initial value. Similarly, when the tool is in a loaded condition and the controller 250 determines that the variation has not satisfied the threshold in step 400, the controller 250 proceeds to block 404 to determine that the breaker 10 is now in a no-load condition. Upon entering block 404, the controller 250 also increases the threshold (e.g., to a value between 110-140% of the initial threshold). This increased threshold may be used by the controller when subsequently executing step 396. In some embodiments, this increased threshold is used for a certain amount of time or number passes through block 396, and then the controller 250 returns the threshold to its initial value. In some embodiments, to provide hysteresis, the controller 250 may turn off determining whether the characteristic value has satisfied a threshold for a certain amount of time. For example, the controller 250 may implement a timer after switching from the loaded condition to the no-load condition or from the no-load condition to the loaded condition before the controller 250 next determines whether the characteristic value satisfies the threshold value.

Alternatively, the method 388 may be modified to resemble methods 330 and 358 such that a first characteristic variation threshold (or first known characteristic profile) is used to determine load state in the loaded condition and a second characteristic variation threshold (or second known characteristic profile) is used to determine load state in the unloaded (or no load) condition.

As shown in FIG. 20, in some embodiments the breaker 10 includes one or more light sources 412, 414. In the illustrated embodiment, two light sources 412, 414 are located on the front side 17 of the housing 14. Alternatively, the breaker 10 may include more or fewer light sources 412, 414, and the light sources 412, 414 could be located elsewhere (e.g., on the bottom end 16 of the housing 14 or on the cylinder 62). The light sources 412, 414 emit light 416 that illuminates a workpiece 420 on which the above-described chiseling operation is performed. The light 416 projects an incident area 424 on the workpiece 420 having a surface area 428. In the illustrated embodiment, the incident area 424 is circular, but in other embodiments, the incident area 424 may take other shapes. In the illustrated embodiment, when viewing the breaker 10 from the front side, the first light source 412 is offset from and located on a first side of the chisel axis 74 and the second light source 414 is offset from and located on an opposite second side of the chisel axis 74.

In some embodiments, the one or more light sources 412, 414 are spot lights. In other embodiments, the one or more light sources 412, 414 are flood lights. In some embodiments, one light source 412 is a spot light and one light source 414 is a flood light. In some embodiments, the one or more light sources 412, 414 are LEDs. In some embodiments, the breaker 10 includes a pair of lenses 432, 434 through which light produced by the light sources 412, 414 respectively is respectively projected. In some embodiments, the lens may be adjusted to diffuse the light 416 and thereby increase the surface area 428 of the incident area 424. In some embodiments, the lens may be adjusted to narrow the focus of the light 416 on the workpiece contacted by the chisel 24, thereby decreasing the surface area 428. The light 416 produced by the one or more light sources 412, 414 makes it easier for an operator to monitor the chiseling operation on the workpiece 420, particularly in low light conditions.

In some embodiments, the breaker 10 includes a lubricant (e.g., Zerk) fitting 440 proximate the top end 15 of the housing 14 (FIG. 22). The Zerk fitting 440 is arranged in an opening 442 on the top side 15 of the housing 14 that is covered by a selectively removable cover 444 as shown in FIG. 22. A tube 448 connects the Zerk fitting 440 to a crank fitting 450 on the crank case 20 that provides a fluid coupling to the crank case 20 and the percussion mechanism 22 therein. The Zerk fitting 440 provides access for an operator to supply grease or another lubricant to the percussion mechanism 22 via the tube 448 and crank fitting 450. Because the Zerk fitting 440 is arranged proximate the top end 15 of the housing 14, which the operator is able to access with convenience, the Zerk fitting 440 is conveniently located for an operator to supply grease to the percussion mechanism 22 without removing the crank case 20 from the housing 14.

As shown in FIGS. 23 and 24, the bottom end 16 of the housing 14 includes a carrying handle 452 on the bottom end 16 of the housing 14 and configured to be grasped during a non-operative state of the breaker 10. In the embodiment illustrated in FIGS. 23 and 24, the carrying handle 452 is a recess 456 in the bottom end 16 of the housing 14. The recess 456 substantially defines a handle plane 460 that defines an acute angle α with respect to the striker plane 166. In some embodiments, the angle α is between 5 degrees and 60 degrees. In the illustrated embodiment, the angle α is approximately 30 degrees. The relative orientation between the recess 456 and the striker plane 460 makes the operator's grip more secure when the operator slides a hand into the recess 456. In some embodiments, the recess 456 is molded into the bottom end 16 of the housing 14. Because the handle 452 is proximate the center of gravity CG of the breaker 10 (FIG. 24), when an operator grasps the handle 452, the breaker 10 is less likely to wobble or create a moment that might otherwise cause the breaker 10 to tip in any particular direction, making the breaker 10 more stable (and thus more comfortable for the user) when being carried to and from a job site.

As shown in FIGS. 20 and 21, the battery pack 26 is removably received in a battery receptacle 464 on the front side 17 of the housing 14 to transfer current from the battery pack 26 to the motor 18 via the controller 250. With reference to FIGS. 26 and 27, the battery pack 26 includes a battery pack housing 468 with a support portion 472 and a first terminal 476 that is electrically connected to a plurality of battery cells 480 within the pack housing 468. The support portion 472 provides a slide-on arrangement with a projection/recess portion 484 cooperating with a complementary projection/recess portion 488 (shown in FIGS. 20 and 21) of the battery receptacle 464. In the embodiment illustrated in FIGS. 20, 21 and 26, the projection/recess portion 484 of the battery pack 26 is a guide rail and the projection/recess portion 488 of the battery receptacle 464 is a guide recess. A similar battery pack is described and illustrated in U.S. patent application Ser. No. 16/025,491 filed Jul. 2, 2018, the entire content of which is incorporated herein by reference. In some embodiments, the battery cells 480 have a nominal voltage of up to about 80 V. In some embodiments, the battery cells 480 have a nominal voltage of up to about 120 V. In some embodiments, the battery pack 26 has a weight of up to about 6 lb. In some embodiments, each of the battery cells 480 has a diameter of up to 21 mm and a length of up to about 71 mm. In some embodiments, the battery pack 26 includes up to twenty battery cells 480. In some embodiments, the battery cells 480 are two cell strings of twenty series connected cells, the cell strings being connected in parallel. In some embodiments, the battery cells 480 are operable to output a sustained operating discharge current of between about 40 A and about 60 A. In some embodiments, each of the battery cells 480 has a capacity between about 3.0 Ah and about 5.0 Ah.

FIG. 21 illustrates the battery receptacle 464 of the breaker 10 in accordance with some embodiments. The battery receptacle 464 includes the projection/recess 488, a second terminal 492, a latch 496, and a power disconnect switch. The projection/recess 488 cooperates with the projection/recess 484 of the battery pack 26 to attach the battery pack 26 to the battery receptacle 464 of the breaker 10. When the battery pack 26 is attached to the breaker 10, the second terminal 492 and the first terminal 476 are electrically connected to each other. The latch 496 protrudes from a surface of the battery receptacle 464 and is configured to engage the battery pack 26 to maintain engagement between the battery pack 26 and the battery receptacle 464. Thus, the battery pack 26 is connectable to and supportable by the battery receptacle 464 such that the battery pack 26 is supportable by the housing 14 of the breaker 10.

In other embodiments (not shown), the latch 496 may be disposed at various locations (e.g., on a sidewall, an end wall, an upper end wall etc., of the battery receptacle 464) such that the latch 496 engages corresponding structure on the battery pack 26 to maintain engagement between the battery pack 26 and the battery receptacle 464. The latch 496 is slidably disposed in the receptacle 464 and is biased toward a latching position by a biasing member to protrude through a surface of the battery receptacle 464 and into a cavity in the battery pack 26. The latch 496 is moveable to an unlatched position by an actuator 500 (FIG. 21).

The power disconnect switch (e.g., a micro-switch) facilitates electrical connection/disconnection of the battery pack 26 from the battery receptacle 464 during actuation of the actuator 500 to withdraw the latch 496 from the battery pack 26. The power disconnect switch may act to electrically disconnect the battery pack 26 from the breaker 10 prior to removal of the battery pack 26 from the battery receptacle 464. The power disconnect switch is actuated when the latch member 500 is moved from the latched position (i.e., when the latch member 500 is completely within the cavity of the battery pack 26) to an intermediate position. The power disconnect switch is electrically connected to the controller 250 and may generate an interrupt to indicate that the battery pack 26 is being disconnected from the breaker 10. When the controller 250 receives the interrupt, the controller 250 begins a power down operation to safely power down the breaker 10. A similar latching mechanism and disconnect switch is described and illustrated in U.S. patent application Ser. No. 16/025,491, which has been incorporated herein by reference.

As shown in FIG. 28, in some embodiments, the motor 18 includes a motor housing 504 having an outer diameter 508, a stator 512 having a nominal outer diameter 516 of up to about 80 mm, a rotor 520 having an output shaft 524 and supported for rotation within the stator 512, and a fan 528. A similar motor is described and illustrated in U.S. patent application Ser. No. 16/025,491, which has been incorporated herein by reference. In some embodiments, the motor 18 is a brushless direct current motor. In some embodiments, the motor 18 has a power output of at least about 2760 W. In some embodiments, the fan 528 has a diameter 532 that is larger than the outer diameter 508 of the motor housing 504. In some embodiments, the motor 18 can be stopped with an electronic clutch (not shown) for quick overload control. In some embodiments, the motor 18 has a volume of up to about 443,619 mm³. In some embodiments, the motor 18 has a weight of up to about 4.6 lb. The housing 14 includes an inlet vent and an outlet vent, such that the motor fan 528 pulls air through the inlet vent and along the control electronics to cool the control electronics before the air is exhausted through the outlet vent.

The table below shows some of the performance characteristics of the breaker 10 that are achieved with the battery pack 26 and the motor 18 as described above, compared to a prior art breaker. The first row of the table shows the categories of performance characteristics, including the impact energy (J) for each impact of the striker 70 on a chisel, the blow frequency of the striker 70 (on the chisel, measure in beats per minute (bpm)), the blow power (W) of each impact on the chisel, the impact energy to mass ratio (J/kg), the power to weight ratio (W/kg), and the impact energy per minute (kJ/min) delivered by the chisel. The second row of the table shows the measured performance characteristics of a prior art corded AC breaker. The third row of the table shows the measured performance characteristics of the breaker 10.

Impact Impact Impact Blow Blow Energy/ Power/ Energy Mass Energy Frequency Power Mass Mass (kJ)/ (kg) (J) (bpm) (W) (J/kg) (W/kg) minute Prior Art 25.0 64.0 1300 1387 2.6 55.5 83.2 Breaker Breaker 28.0 74.6 1224 1521 2.7 54.4 91.3 10

Notably, the battery powered breaker 10 is able to achieve a higher impact energy (J) and blow power (W) per impact of the chisel 24 than the prior art corded AC breaker, thus allowing the breaker 10 to deliver more impact energy (kJ) per minute. Also, the breaker 10 has a higher impact energy to weight ratio (W/kg) as the prior art AC breaker, and also a close power to mass ratio (W/kg), despite being battery powered. Thus, the breaker 10 affords an operator greater operational convenience due to its enhanced portability, while still achieving greater or nearly the same performance characteristics as the prior art corded AC breaker.

Various features of the invention are set forth in the following claims. 

What is claimed is:
 1. A percussion tool comprising: a housing; an electric motor positioned within the housing; a battery pack supported by the housing for providing power to the motor, the battery pack including a plurality of battery cells having a nominal voltage of up to 120 Volts; and a percussion mechanism driven by the motor and including a striker supported for reciprocation in the housing, wherein the percussion tool has a ratio of impact energy to mass that is greater than or equal to 2.5 Joules/kilogram.
 2. The percussion tool of claim 1, wherein the electric motor is a brushless direct current electric motor.
 3. The percussion tool of claim 1, further comprising a battery receptacle on the housing to which the battery pack is mechanically and electrically connected.
 4. The percussion tool of claim 1, wherein each of the battery cells has a diameter of up to about 21 mm and a length of up to about 71 mm.
 5. The percussion tool of claim 1, wherein the battery pack includes up to 20 battery cells.
 6. The percussion tool of claim 1, wherein the battery cells are at least two cell strings of series connected cells, each cell string being connected in parallel.
 7. The percussion tool of claim 1, wherein each of the battery cells has a capacity of between about 3.0 Ah and about 5.0 Ah.
 8. The percussion tool of claim 1, wherein the percussion tool has a ratio of blow power to mass that is greater than or equal to 50 W/kg.
 9. The percussion tool of claim 1, wherein the percussion tool delivers greater than or equal to 85 kJ of impact energy per minute.
 10. The percussion tool of claim 1, wherein the motor is operable to output more than 1800 W.
 11. The percussion tool of claim 1, wherein the battery cells have a sustained operating discharge current more than 25 A.
 12. The percussion tool of claim 1, wherein the motor is operable to output at least about 2760 W.
 13. The percussion tool of claim 12, wherein the battery cells have a sustained operating discharge current of between about 40 A and about 60 A.
 14. A percussion tool comprising: a housing; an electric motor positioned within the housing; a battery pack supported by the housing for providing power to the motor, the battery pack including a plurality of battery cells having a nominal voltage of up to 120 Volts; and a percussion mechanism driven by the motor and including a striker supported for reciprocation in the housing, wherein the percussion tool has a ratio of blow power to mass that is greater than or equal to 50 W/kg.
 15. The percussion tool of claim 14, wherein the electric motor is a brushless direct current electric motor.
 16. The percussion tool of claim 14, further comprising a battery receptacle on the housing to which the battery pack is mechanically and electrically connected.
 17. The percussion tool of claim 14, wherein each of the battery cells has a diameter of up to about 21 mm and a length of up to about 71 mm.
 18. The percussion tool of claim 14, wherein the battery pack includes up to 20 battery cells.
 19. The percussion tool of claim 14, wherein the battery cells are at least two cell strings of series connected cells, each cell string being connected in parallel.
 20. The percussion tool of claim 14, wherein each of the battery cells has a capacity of between about 3.0 Ah and about 5.0 Ah.
 21. The percussion tool of claim 14, wherein the percussion tool delivers greater than or equal to 85 kJ of impact energy per minute.
 22. The percussion tool of claim 14, wherein the motor is operable to output more than 1800 W.
 23. The percussion tool of claim 14, wherein the battery cells have a sustained operating discharge current more than 25 A.
 24. The percussion tool of claim 14, wherein the motor is operable to output at least about 2760 W.
 25. The percussion tool of claim 24, wherein the battery cells have a sustained operating discharge current of between about 40 A and about 60 A.
 26. A percussion tool comprising: a housing; an electric motor positioned within the housing; a battery pack supported by the housing for providing power to the motor, the battery pack including a plurality of battery cells having a nominal voltage of up to 120 Volts; and a percussion mechanism driven by the motor and including a striker supported for reciprocation in the housing; wherein the percussion tool delivers greater than or equal to 85 kJ of impact energy per minute.
 27. The percussion tool of claim 26, wherein the electric motor is a brushless direct current electric motor.
 28. The percussion tool of claim 26, further comprising a battery receptacle on the housing to which the battery pack is mechanically and electrically connected.
 29. The percussion tool of claim 26, wherein each of the battery cells has a diameter of up to about 21 mm and a length of up to about 71 mm.
 30. The percussion tool of claim 26, wherein the battery pack includes up to 20 battery cells.
 31. The percussion tool of claim 26, wherein the battery cells are at least two cell strings of series connected cells, each cell string being connected in parallel.
 32. The percussion tool of claim 26, wherein each of the battery cells has a capacity of between about 3.0 Ah and about 5.0 Ah.
 33. The percussion tool of claim 26, wherein the motor is operable to output more than 1800 W.
 34. The percussion tool of claim 26, wherein the battery cells have a sustained operating discharge current more than 25 A.
 35. The percussion tool of claim 26, wherein the motor is operable to output at least about 2760 W.
 36. The percussion tool of claim 35, wherein the battery cells have a sustained operating discharge current of between about 40 A and about 60 A. 